You are hereJanuary 25, 2019
Stem Cells Regulate Their Fate by Altering Their Stiffness
FREIBURG (DE), January 2019 — In adults, mesenchymal stems cells (MSCs) are primarily found in bone marrow and they play a vital role in repair of damaged organs. The transformation of a single MSC into complex tissue like cartilage and bone starts with its association with other MSCs in order to form microscopic clusters via a process termed as condensation.
While it is known that this condensation step is important for skeletal development the exact role it plays in formation of bone and cartilage is not understood. A team led by Prasad Shastri, Ph.D., and Melika Sarem, Ph.D., of the Institute for Macromolecular Chemistry at the University of Freiburg present evidence for autonomous control of chondrogenesis in MSCs. These findings are published in Stem Cell Research & Therapy.
They discovered that reducing the number of cells participating in the condensation process leads to the activation of an intrinsic differentiation program. This prompts MSCs to become cartilage cells, even in the absence of chondro-inductive growth factors irrespective of donor age and sex. Drs. Sarem and Shastri further identified that two cell-membrane proteins, Caveolin-1 and N-Cadherin, are differentially regulated during the condensation step and function as interactive forces like a yin-yang of chondrogenic differentiation. "The fact that we need lesser cells to create better quality tissue is extremely exciting as it opens new avenues for stem cell therapies," Dr. Sarem said.
In collaboration with Oliver Otto, Ph.D., at the University of Greifswald, the Freiburg researchers demonstrated that the chondrogenic potential of MSCs correlates with emergence of a stiffer phenotype and increase in cell size. Their findings allude to a hitherto unknown mechanobiology paradigm in MSC differentiation.
"Since MSCs harvested from adult bone marrow are a heterogeneous population of cells and their ability to undergo differentiation into cartilage or bone cells varies from donor to donor, our findings have significant implication for MSC-based strategies for engineering cartilage and bone tissue," Dr. Shastri said.
Immunofluorescence staining of matrix proteins in engineered cartilage. Image courtesy of Institut für Makromolekulare Chemie.